Features

Shatter the boundaries of what's possible with NVIDIA® Quadro RTX™ 5000. Powered by the NVIDIA Turing™ architecture and the NVIDIA RTX™ platform, it fuses ray tracing, deep learning and advanced shading to supercharge next-generation workflows. Creative and technical professionals can make more informed decisions faster and tackle demanding design and visualization workloads with ease.

New RT Cores and Tensor Cores bring the power of real-time ray tracing and AI-enhanced workflows to millions of design and creative professionals. Combined with NVIDIA NVLink™ technology, RTX 5000 scales graphics memory and performance to drive the most demanding rendering, AI, and visual computing workloads. And the all-new VirtualLink® provides connectivity to next-generation, high-resolution VR HMDs to let you view your work in the most compelling virtual environments. Welcome to the future of professional visual computing.

3. Next-Gen Memory

4. NVIDIA Turing GPU Architecture

Armed with the all-new RTCore for ray tracing, 384 Tensor Cores for AI and 3072 CUDA cores for parallel computing, NVIDIA Turing is simply the world's most advanced GPU.

Multi-GPU Technology

Performance Features

Turing GPU Architecture

Based on state-of-the-art 12nm FFN (FinFET NVIDIA) high-performance manufacturing process customized for NVIDIA to incorporate 3072 CUDA cores, the Quadro RTX 5000 GPU is the most powerful computing platform for HPC, AI, VR and graphics workloads on professional desktops. The Turing GPU architecture enables the biggest leap in computer real-time graphics rendering since NVIDIA's invention of programmable shaders in 2001. It includes 13.6 billion transistors on die size of 545 mm2. Able to deliver more than 11.2 TFLOPS of single-precision (FP32), 22.3 TFLOPS of half-precision (FP16), 44.6 TOPS of integer-precision (INT8), and 89.2 TFLOPs of tensor operation capability, it supports a wide range of compute-intensive workloads flawlessly.

RT Cores

New dedicated hardware-based ray-tracing technology allows the GPU for the first time to real-time render film quality, photorealistic objects and environments with physically accurate shadows, reflections, and refractions. The real-time ray-tracing engine works with NVIDIA OptiX, Microsoft DXR, and Vulkan APIs to deliver a level of realism far beyond what is possible using traditional rendering techniques. RT cores accelerate the Bounding Volume Hierarchy (BVH) traversal and ray casting functions using low number of rays casted through a pixel.

NVIDIA GPU BOOST 4.0

Automatically maximize application performance without exceeding the power and thermal envelope of the card. Allows applications to stay within the boost clock state longer under higher temperature threshold before dropping to a secondary temperature setting base clock. This feature requires implementation by software applications and it is not a stand-alone utility. Please contact quadrohelp@nvidia.com for details on availability.

Advanced Streaming Multiprocessor (SM) Architecture

Combined shared memory and L1 cache improve performance significantly, while simplifying programming and reducing the tuning required to attain best application performance. Each SM contains 96 KB of L1/shared memory, which can be configured for various capacities depending on compute or graphics workload. For compute cases, up to 64 KB can be allocated to the L1 cache or shared memory, while graphics workload can allocate up to 48 KB for shared memory; 32 KB for L1 and 16 KB for texture units. Combining the L1 data cache with the shared memory reduces latency and provides higher bandwidth.

Mixed-Precision Computing

Double the throughput and reduce storage requirements with 16-bit floating point precision computing to enable the training and deployment of larger neural networks. With independent parallel integer and floating-point data paths, the Turing SM is also much more efficient on workloads with a mix of computation and addressing calculations.

Error Correcting Code (ECC) on Graphics Memory

Graphics Preemption

Pixel-level preemption provides more granular control to better support time-sensitive tasks such as VR motion tracking.

Compute Preemption

Preemption at the instruction-level provides finer grain control over compute tasks to prevent long-running applications from either monopolizing system resources or timing out.

H.264 and HEVC Encode/Decode Engines

Deliver faster than real-time performance for transcoding, video editing, and other encoding applications with two dedicated H.264 and HEVC encode engines and a dedicated decode engine that are independent of 3D/compute pipeline.

Single Instruction, Multiple Thread (SIMT)

New independent thread scheduling capability enables finer-grain synchronization and cooperation between parallel threads by sharing resources among small jobs.

Features

Shatter the boundaries of what's possible with NVIDIA® Quadro RTX™ 5000. Powered by the NVIDIA Turing™ architecture and the NVIDIA RTX™ platform, it fuses ray tracing, deep learning and advanced shading to supercharge next-generation workflows. Creative and technical professionals can make more informed decisions faster and tackle demanding design and visualization workloads with ease.

New RT Cores and Tensor Cores bring the power of real-time ray tracing and AI-enhanced workflows to millions of design and creative professionals. Combined with NVIDIA NVLink™ technology, RTX 5000 scales graphics memory and performance to drive the most demanding rendering, AI, and visual computing workloads. And the all-new VirtualLink® provides connectivity to next-generation, high-resolution VR HMDs to let you view your work in the most compelling virtual environments. Welcome to the future of professional visual computing.

3. Next-Gen Memory

4. NVIDIA Turing GPU Architecture

Armed with the all-new RTCore for ray tracing, 384 Tensor Cores for AI and 3072 CUDA cores for parallel computing, NVIDIA Turing is simply the world's most advanced GPU.

Multi-GPU Technology

Performance Features

Turing GPU Architecture

Based on state-of-the-art 12nm FFN (FinFET NVIDIA) high-performance manufacturing process customized for NVIDIA to incorporate 3072 CUDA cores, the Quadro RTX 5000 GPU is the most powerful computing platform for HPC, AI, VR and graphics workloads on professional desktops. The Turing GPU architecture enables the biggest leap in computer real-time graphics rendering since NVIDIA's invention of programmable shaders in 2001. It includes 13.6 billion transistors on die size of 545 mm2. Able to deliver more than 11.2 TFLOPS of single-precision (FP32), 22.3 TFLOPS of half-precision (FP16), 44.6 TOPS of integer-precision (INT8), and 89.2 TFLOPs of tensor operation capability, it supports a wide range of compute-intensive workloads flawlessly.

RT Cores

New dedicated hardware-based ray-tracing technology allows the GPU for the first time to real-time render film quality, photorealistic objects and environments with physically accurate shadows, reflections, and refractions. The real-time ray-tracing engine works with NVIDIA OptiX, Microsoft DXR, and Vulkan APIs to deliver a level of realism far beyond what is possible using traditional rendering techniques. RT cores accelerate the Bounding Volume Hierarchy (BVH) traversal and ray casting functions using low number of rays casted through a pixel.

NVIDIA GPU BOOST 4.0

Automatically maximize application performance without exceeding the power and thermal envelope of the card. Allows applications to stay within the boost clock state longer under higher temperature threshold before dropping to a secondary temperature setting base clock. This feature requires implementation by software applications and it is not a stand-alone utility. Please contact quadrohelp@nvidia.com for details on availability.

Advanced Streaming Multiprocessor (SM) Architecture

Combined shared memory and L1 cache improve performance significantly, while simplifying programming and reducing the tuning required to attain best application performance. Each SM contains 96 KB of L1/shared memory, which can be configured for various capacities depending on compute or graphics workload. For compute cases, up to 64 KB can be allocated to the L1 cache or shared memory, while graphics workload can allocate up to 48 KB for shared memory; 32 KB for L1 and 16 KB for texture units. Combining the L1 data cache with the shared memory reduces latency and provides higher bandwidth.

Mixed-Precision Computing

Double the throughput and reduce storage requirements with 16-bit floating point precision computing to enable the training and deployment of larger neural networks. With independent parallel integer and floating-point data paths, the Turing SM is also much more efficient on workloads with a mix of computation and addressing calculations.

Error Correcting Code (ECC) on Graphics Memory

Graphics Preemption

Pixel-level preemption provides more granular control to better support time-sensitive tasks such as VR motion tracking.

Compute Preemption

Preemption at the instruction-level provides finer grain control over compute tasks to prevent long-running applications from either monopolizing system resources or timing out.

H.264 and HEVC Encode/Decode Engines

Deliver faster than real-time performance for transcoding, video editing, and other encoding applications with two dedicated H.264 and HEVC encode engines and a dedicated decode engine that are independent of 3D/compute pipeline.

Single Instruction, Multiple Thread (SIMT)

New independent thread scheduling capability enables finer-grain synchronization and cooperation between parallel threads by sharing resources among small jobs.

Delivery estimates

The estimated time to ship for each product we sell is detailed on the individual product page just underneath the price. From when your items ship, products typically arrive within 1 working day for North Island deliveries and 2 working days for South Island deliveries. Rural deliveries may take an extra working day, and bulk deliveries may take an extra 2-4 working days.

Shipping costs

Shipping costs vary based on your location and the items being shipped and in some cases shipping may even be FREE.

To calculate what the shipping costs will be for your order, add the items you are interested in to your cart, view the Shopping Cart page, and select your 'Delivery Area' to calculate the shipping cost.

Shipping security and insurance

All orders shipped by PB Tech are sent via a courier with a signature required for each delivery. In some cases, and only where you have given the courier company permission to leave orders at a designated location, your order may be delivered without requiring a signature. All orders sent by PB Tech are fully insured in the unlikely event that your item(s) are damaged or go missing in transit.

Pick-up options

You can pick-up your online order from any of our branches nationwide. You can select which branch you want to pick up from on the Shopping Cart page. Please note that if the branch you want to pick up from doesn't have stock of one or more of the items in your order, it may take 3-4 working days to transfer the stock to the branch so your order can be fulfilled.

Overseas shipments

PB Tech regularly ships overseas to Australia and beyond. If you are located in Australia, you can order directly from our Australian site www.pbtech.com/au. If you are from another country you can order from www.pbtech.com

NZ Logistics Centre

PB Tech holds a significant amount of stock in our New Zealand based logistics centre and can ship stock from this location usually within 2-4 working days (see the timeframes mentioned on each product page for more accurate delivery estimates).

In most cases, items ordered from the NZ Logistics Centre are first transferred to our Head Office / Distribution Centre before being shipped to the final destination.

Pick-ups from the NZ Logistics Centre

Unfortunately no pick-up options are available directly from this location, you can select a pick up from one of our branches however and we will transfer your order there so you can pick up.

Suppliers

Products marked as 'In stock with Supplier' are shipped from one of our suppliers / vendors. The time frame for shipments can vary so please refer to the shipping time frames mentioned on each product page for more accurate delivery estimates.

In most cases, items ordered from suppliers are first transferred to our Head Office / Distribution Centre before being shipped to the final destination.

Returns & Warranty

7 day right of exchange

If you change your mind after making a purchase, or realise you have ordered the incorrect item, you can enjoy the peace of mind that we offer a 7 day exchange policy.

To exchange a product, goods must be sealed / unopened, with packaging in original condition, and accompanied by a valid receipt dated no more than 7 calendar days from when you request an exchange.

If there is not a suitable product that can be exchanged for your returned item you will be offered a credit on your account or gift card based on the value paid at the time of purchase.

Please note, items purchased on finance cannot be exchanged for a gift card.

Hassle free warranty service

If your product develops a fault within the manufacturer warranty period, you can either contact the manufacturer directly (some manufacturers provide a high level of warranty service - including free pickup or in some cases onsite repair), or return to one of our services centres / stores. Where the product has been directly imported by PB Tech, you need to contact us directly or present the product at any one of our service centres / stores together with your proof of purchase.

If your product develops a fault outside of the manufacturer warranty or PB Tech warranty period, we offer a full repair service and are an authorised repair agent for leading brands such as Samsung, HP, Toshiba, Lenovo and more.